COMPARISON OF GENERATOR AND MOTOR ACTION

It has been seen that the same machine can be used as a DC generator or as a DC motor. When it converts mechanical energy (or power) into electrical energy (or power), it is called a DC generator and when it is used for reversed operation, it is called a DC motor. Table 11.1 gives the comparison between the generator and the motor action.

Table 11.1  Comparison between the Generator and the Motor Action

Generator ActionMotor Action
image
Fig. 11.39 (a) Generator
image
Fig. 11.39 (b) Motor
1. In generator action, the rotation is due to mechanical torque, and therefore, Tm and ω are in the same direction.1. In motor action, the rotation is due to electromagnetic torque, and therefore, Te and ω are in the same direction.
2. The frictional torque Tf acts in opposite direction to rotation ω.2. The frictional torque Tf acts in opposite direction to rotation ω.
3. Electromagnetic torque Te acts in opposite direction to mechanical torque Tm so that ωTm = ωTe + ωTf.3. Mechanical torque Tm acts in opposite direction to electromagnetic torque Te so that ωTe = ωTm + ωTf.
4. In generator action, an emf is induced in the armature conductors that circulate current in the armature when load is connected to it. Hence, both e and i are in the same direction.4. In motor action, current is impressed to the armature against the induced emf (e), and therefore, current flows in the opposite direction to that of induced emf.
5. In generator action, E > V5. In motor action, E < V
6. In generator action, the torque angle θ is leading.6. In motor action, the torque angle θ is lagging.
7. In generator action, mechanical energy is converted into electrical energy7. In motor action, electrical energy is converted into mechanical energy.

Example 11.19

A 50 H.P., 400 V, 4-pole, 1,000 rpm, DC motor has flux per pole equal to 0.027 Wb. The armature having 1,600 conductors is wave connected. Calculate the gross torque when the motor takes 70 A.

Solution:

Torque developed, image

where P = 4; ɸ = 0.027 Wb; Z = 1,600; Ia = 70 A; A = 2 (wave connected)

image

Example 11.20

The induced emf in a DC machine is 200 V at a speed of 1,200 rpm. Calculate the electromagnetic torque developed at an armature current of 15 A.

Solution:

Here, Eb = 200 V; N = 1,200 rpm; Ia = 15 A

Now, power developed in the armature,

image

Example 11.21

A 4-pole DC motor has a wave-wound armature with 594 conductors. The armature current is 40 A and flux per pole is 7.5 mWb. Calculate H.P. of the motor when running at 1,440 rpm.

Solution:

Torque developed,

image

Power developed = ω T watt, where image

image

or

image

Example 11.22

A 6-pole, lap-wound DC motor takes 340 A when the speed is 400 rpm. The flux per pole is 0.05 Wb and the armature has 864 turns. Neglecting mechanical losses, calculate the BHP of the motor.

(P.T.U. May 2010)

Solution:

Here, P = 6; A = P = 6 (lap wound); IL = 340 A; N = 400 rpm,

ɸ = 0.05 Wb; number of turns = 864

Z = 864 × 2 = 1,728

Back emf, image

Armature current, Ia = IL = 340 A

Power developed = Eb × Ia = 576 × 340 = 195,840 W

Neglecting losses, image

11.20  TYPES OF DC MOTORS

On the basis of the connections of armature and their field winding, DC motors can be classified as follows.

11.20.1  Separately Excited DC Motors

The conventional diagram of a separately excited DC motor is shown Figure 11.40. Its voltage equation will be

image

Fig. 11.40  Conventional diagram of a separately excited DC motor

Eb = V − Ia Ra − 2vb (where vb is voltage drop per brush)

11.20.2  Self-excited DC Motors

These motors can be further classified as follows:

  1. Shunt motors: Their conventional diagram is shown in Figure 11.41. imageFig. 11.41  Conventional diagram of a shunt wound DC motorImportant relations: Ish = V/Rsh; Ia = IL − IshEb = V − Ia Ra − 2vb (where vb is voltage drop per brush)
  2. Series motor: Its conventional diagram is shown in Figure 11.42imageFig. 11.42  Conventional diagram of a series wound DC motorImportant relations: IL = Ia = IseEb = V − Ia (Ra + Rse) − 2vb
  3. Compound motor: Its conventional diagram (for long shunt) is shown in Figure 11.43. imageFig. 11.43  Conventional diagram of a compound wound DC motorimageIn all the above mentioned voltage equations, the brush voltage drop vb is sometimes neglected since its value is very small.The compound motor can be further subdivided as follows:
    1. Cumulative compound motors: In these motors, the flux produced by both the windings is in the same direction, that is, ɸr = ɸsh + ɸse 
    2. Differential compound motors: In these motors, the flux produced by the series field winding is opposite to the flux produced by the shunt field winding, that is, ɸr = ɸsh − ɸse 

Example 11.23

A 4-pole DC motor has a wave-wound armature with 594 conductors. The armature current is 40 A and flux per pole is 7.5 mWb. Calculate H.P. of the motor when running at 1,440 rpm

Solution:

Torque developed,

image

Power developed = ωT watts, where image

image

Example 11.24

A 6-pole lap-wound shunt motor has 500 conductors in the armature. The resistance of armature path is 0.05 Ω. The resistance of shunt field is 25 Ω. Find the speed of the motor when it takes 120 A from a DC mains of 100 V supply. Flux per pole is 2 × 10−2 Wb.

Solution:

The conventional diagram of the motor is shown in Figure 11.44

image

Fig. 11.44  Conventional diagram as per data

image

Ia = IL − Ish = 120 − 4 = 116 − A

 

Eb = V − Ia Ra

 

= 100 − 116 × 0.05 = 94.2 V

Now,

image

or

N = 565.2 rpm

Example 11.25

A 6-pole, 440 V DC motor has 936 wave-wound armature conductors. The useful flux per pole is 25 mWb. The torque developed is 45.5 kgm. If armature resistance is 0.5 Ω, then calculate (i) armature current and (ii) speed.

(P.T.U.)

Solution:

Number of poles, P = 6

Number of armature conductors, Z = 936

Flux per pole, ɸ = 25 mWb = 25 × 103 Wb

Number of parallel path, A = 2 (wave-wound armature)

Terminal voltage, V = 440 V

Armature resistance, Ra = 0.5 Ω

Torque developed, T = 45.5 kgm = 45.5 × 9.81 = 446.35 Nm

  1. Using the relation, imageArmature current, image
  2. Induced emf, E = V − Ia Ra (motor action) = 440 − 39.95 × 0.5 = 420 V

Using the relation, ωT = EIa   or   image

Speed

image

Example 11.26

A 400 V DC motor takes an armature current of 100 A when its speed is 1,000 rpm. If the armature resistance is 0.25 Ω, then calculate the torque produced in Nm.

(P.T.U.)

Solution:

Terminal voltage, V = 400 V

Armature current, Ia = 100 A

Armature resistance, Ra = 0.25 Ω

Speed, N = 1,000 rpm

Induced emf, E = V − Ia Ra (motor action)

 

= 400 − 100 × 0.25 = 375 V

Using the relation, ωT = EIa or image

Therefore, torque produced, image

Example 11.27

The electromagnetic torque developed in a DC machine is 80 Nm for an armature current of 30 A. What will be the torque for a current of 15 A? Assume constant flux. What is the induced emf at a speed of 900 rpm and an armature current of 15 A?

Solution:

Torque developed, T1 = 80 Nm

Armature current, Ia1 = 30 A

Armature current, Ia2 = 15 A

Let the torque developed is T2 Nm when the armature current is 15 A.

Now,

 

T ∝ fIa

When flux f is constant, T ∝ Ia

Let the torque developed is T2 Nm when the armature current is 15 A.

Now,

 

T α ɸIa

When flux ɸ is constant, T ∝ Ia

Therefore,

image

or

image

Power developed in the armature = E2Ia2 = ω2T2

where

image
image

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